BEGIN:VCALENDAR VERSION:2.0 PRODID:-//UM//UM*Events//EN CALSCALE:GREGORIAN BEGIN:VTIMEZONE TZID:America/Detroit TZURL:http://tzurl.org/zoneinfo/America/Detroit X-LIC-LOCATION:America/Detroit BEGIN:DAYLIGHT TZOFFSETFROM:-0500 TZOFFSETTO:-0400 TZNAME:EDT DTSTART:20070311T020000 RRULE:FREQ=YEARLY;BYMONTH=3;BYDAY=2SU END:DAYLIGHT BEGIN:STANDARD TZOFFSETFROM:-0400 TZOFFSETTO:-0500 TZNAME:EST DTSTART:20071104T020000 RRULE:FREQ=YEARLY;BYMONTH=11;BYDAY=1SU END:STANDARD END:VTIMEZONE BEGIN:VEVENT DTSTAMP:20251003T074234 DTSTART;TZID=America/Detroit:20251016T153000 DTEND;TZID=America/Detroit:20251016T163000 SUMMARY:Workshop / Seminar:Biomedical Engineering Seminar Series DESCRIPTION:Engineering Native Biological Complexity from the Inside–out and Outside–in\nAbstract:\nEngineering heterogenous multicellular tissue with native complexity remains one of the holy grails of regenerative medicine and basic biological research. As success in this regard would yield powerful bioengineered constructs useful in functional transplantation\, high-throughput drug screening\, and fundamental biology investigation\, research efforts in our lab have centered around developing and implementing tools to spatiotemporally customize living cell function both from the “outside–in” and from the “inside–out”. In this talk\, I will discuss some of our group’s recent successes in reversibly modifying the chemical and physical aspects of synthetic cell culture platforms with user-defined and grayscale control\, regulating cell-biomaterial interactions through user-programmable Boolean logic\, engineering microvascular networks that span nearly all size scales of native human vasculature (including capillaries)\, irreversibly photoassembling bioactive proteins within living cells\, and driving biomolecular condensate formation using de novo-designed proteins. Results will highlight our ability to modulate intricate cellular behavior including stem cell differentiation\, protein secretion\, and cell-cell interactions in 4D. UID:140254-21886827@events.umich.edu URL:https://events.umich.edu/event/140254 CLASS:PUBLIC STATUS:CONFIRMED CATEGORIES:seminar,Biotechnology,Biosciences,Bioninterfaces,biomedical engineering,biomedical,Biology,Biointerfaces,Basic Science,Michigan Engineering,Medicine,engineering,engineer,bme LOCATION:Lurie Biomedical Engineering (formerly ATL) - 1130 CONTACT: END:VEVENT BEGIN:VEVENT DTSTAMP:20251001T121431 DTSTART;TZID=America/Detroit:20251016T153000 DTEND;TZID=America/Detroit:20251016T163000 SUMMARY:Workshop / Seminar:IES Energy Seminar Series - Thin-Film Photovoltaics: from Lab to Scale DESCRIPTION:Hosted by Max Shtein \n\nAbstract: \nClean energy generation from photovoltaics (PV) has grown at a historic pace\, reaching 7% of global electricity generation (2000 TWh) in 2024. PV is on track to be the largest renewable energy source by 2029. Today\, silicon PV accounts for roughly 97% of the market share while thin-film PV (mainly CdTe) accounts for the remaining 3%. Silicon PV module prices recently reached a global average low price of <$0.15 per Watt (mainly driven by module production in China)\, making PV a competitive energy source compared to fossil fuels.\n\nResearch and development advances in thin-film PV (with focus on perovskite-based thin-film PV) suggest that novel thin-film PV technologies can not only offer even cheaper PV deployment but also at a lower carbon footprint compared to silicon PV. Perovskite-based thin- film PV has reached record efficiencies of 26.95%\, approaching the silicon single-junction record of 27.81%.\n\nThe prospect of even more affordable PV technology will create new possibilities in emerging green and low-carbon markets.\n\nBiography:\nVera Steinmann is a trained physicist with a Ph.D. in organic photovoltaics from Cologne University in Germany. She developed emerging inorganic thin-film absorbers during her postdoctoral research at the Massachusetts Institute of Technology. Vera joined Kateeva (a Silicon Valley startup in the OLED display industry) in 2016\, and has been with First Solar since 2019\, working on emerging technologies. Vera has helped build and lead the internal perovskite team. Since 2022\, Vera leads the external R&D investment program. UID:138901-21884218@events.umich.edu URL:https://events.umich.edu/event/138901 CLASS:PUBLIC STATUS:CONFIRMED CATEGORIES:Energy,CAEN,Civil and Environmental Engineering,Sustainability,Social Sciences,seminar,Science,Research,Nuclear Engineering and Radiological Sciences,North Campus,Naval Architecture and Marine Engineering,Michigan Engineering,Mechanical Engineering,Materials Science,Law,Interdisciplinary,Industrial and Operations Engineering,Free,Environment,Engineering,Electrical Engineering and Computer Science LOCATION:Electrical Engineering and Computer Science Building - 1311 CONTACT: END:VEVENT BEGIN:VEVENT DTSTAMP:20251013T085306 DTSTART;TZID=America/Detroit:20251016T153000 DTEND;TZID=America/Detroit:20251016T170000 SUMMARY:Workshop / Seminar:Schubert Polynomials Lecture 7: Stanley polynomials DESCRIPTION:After giving a tableau formula for 321-avoiding permutations\, and proving a few more properties of Schubert polynomials\, we look at Stanley polynomials. UID:140592-21887380@events.umich.edu URL:https://events.umich.edu/event/140592 CLASS:PUBLIC STATUS:CONFIRMED CATEGORIES:Mathematics LOCATION:East Hall - 4096 CONTACT: END:VEVENT BEGIN:VEVENT DTSTAMP:20250911T095055 DTSTART;TZID=America/Detroit:20251016T160000 DTEND;TZID=America/Detroit:20251016T171500 SUMMARY:Workshop / Seminar:3D Nanoprinting via Controlled Assembly of Molecules DESCRIPTION:While various 3D printing technology has gained momentum in additive manufacturing\, 3D nanoprinting remains challenging due to its requirement of high spatial precision. Combining scanning probe microscopy and nanolithography\, microfluidic delivery\, this presentation introduces a new chemistry means\, known as “controlled assembly of molecules”\, which enables 3D nanoprinting. While self-assembly of molecules is relatively well-known and frequently utilized in chemical synthesis and material science\, controlled assembly of molecules represents a new concept and approach. The key to controlled assembly is the fact that ultra-small solution droplets exhibit different dynamics from those of larger ones. This new approach enables delivery of sub-femtoliter aqueous droplets containing designed molecules\, which lead to well-defined features with dimensions as small as tens of nanometers\, as illustrated in the Figure. The initial shape of the droplet and the concentration of solutes within the droplet dictate the final assembly of molecules due to the ultrafast evaporation rate and dynamic spatial confinement of the droplets. Applications of this technology in 3D nanoprinting are demonstrated. The level of control demonstrated in this work brings us closer to programmable synthesis for chemistry\, as such benefit applications in materials science\, additive manufacturing\, and nanobiotechnology. UID:138401-21882905@events.umich.edu URL:https://events.umich.edu/event/138401 CLASS:PUBLIC STATUS:CONFIRMED CATEGORIES:Science,Physical Chemistry,Chemistry LOCATION:Chemistry Dow Lab - 1640 CONTACT: END:VEVENT BEGIN:VEVENT DTSTAMP:20251031T123137 DTSTART;TZID=America/Detroit:20251016T160000 DTEND;TZID=America/Detroit:20251016T164500 SUMMARY:Careers / Jobs:Ask a Recruiter: Tips & Tricks DESCRIPTION:Get insider access to Burlington’s recruiting team! In this interactive session\, our recruiters will share tips to help you stand out during the application process. You’ll also have the chance to ask questions and get real-time answers. In this session\, you will:-Learn best practices for applying to Burlington programs-Gaininsights on how to prepare for interviews-Participate in an open Q&\;A with our recruiting team LEARN MORE HERE. Questions? Email earlycareer.recruiting@burlington.com!  UID:138374-21882841@events.umich.edu URL:https://events.umich.edu/event/138374 CLASS:PUBLIC STATUS:CONFIRMED CATEGORIES: LOCATION: CONTACT: END:VEVENT END:VCALENDAR